Spatially and temporally resolving radio-frequency changes in effective cell membrane capacitance

Subcellularly resolved, excitable changes (i.e., those induced by electrical or chemical stimuli) in membrane capacitance, influenced by factors including integralmembrane protein activity, lipid densities and membrane-bound water content, may be used to elucidate nonconductive ion-channel conformational state changes, lipid-raft locations and drug-membrane binding processes. However, membrane capacitance has proven difficult to measure, partially because of bandwidth limitations associated with glass/quartz pipettes used during conventional electrophysiology. To address these challenges, techniques introduced in this thesis integrate the principles of extracellular radio frequency (RF) recording with conventional two-electrode voltage clamp (TEVC) to 1) spatially resolve effective membrane capacitance and 2) monitor excitable changes in effective membrane capacitance. Furthermore, this thesis also introduces a new multielectrode method to approximate electrode-electrolyte interfacial impedance, which might prove useful in electric impedance spectroscopic or electric impedance tomographic applications. Specific contributions include the following: 1) A method that simultaneously estimates double-layer and interelectrode (chamber) impedances, in the linear regime of electrode voltage-current sensitivity, during extracellular electrode-based measurements. This method estimates impedance parameters by applying a nonlinear least-squares regression to measurements between various groups or pairs of a three-electrode system and, unlike previous double-layer approximation methods, can be done without the use of multiple calibration solutions or moveable electrode configurations. 2) A platform capable of visualizing the spatial distribution of membrane capacitance, using extracellular RF electrode recordings, around a single cell. The proof-of-concept for this technique is demonstrated with dielectric maps around polarized Xenopus oocyte membranes. 3) Development and characterization of a platform to enable RF impedancebased measurements around voltage-clamped ShakerB-IR-expressing Xenopus oocytes. Data indicated that the platform was most sensitive to effective changes in oocyte dielectric at 300 kHz and 500 kHz. 4) Temporal characterization of changes in voltage-sensitive RF membrane capacitance associated with ShakerB-IR activation (expressed in Xenopus oocytes) and ShakerB-IR-Cu2+ interactions. Results indicate that extracellular RF-impedance-based measurements can temporally and spatially elucidate changes in excitable cell-membrane capacitance and could supplement conventional electrophysiological techniques to provide a broader understanding of cellular biophysics.